Multiple-stage hydrocarbon conversion with gravity-flowing catalyst particles

ABSTRACT

A multiple-stage catalytic conversion system in which a hydrocarbonaceous charge stock and hydrogen flow serially through a plurality of catalytic reaction zones in each of which the catalyst particles are downwardly movable via gravity-flow. The flow of the product effluent from at least one reaction zone is restricted, as is the flow of the hydrogen-rich vaporous phase separated from the effluent from the last reaction zone and recycled to the first reaction zone. This technique increases the density of the reaction zone feed and the pressure drop within the entire reactor circuit, and thus serves to alleviate the problems associated with the occurrence of stagnant catalyst areas as a result of catalyst particles being &#34;pinned&#34; within the reaction zone and thus unable to assume a downward, gravity-flow pattern. Flow restriction may be effected either before, or after the inter-reaction zone heaters, preferably the former.

APPLICABILITY OF INVENTION

Our invention is directed toward an improved technique for effecting the catalytic conversion of a hydrocarbonaceous reactant stream in a multiple-stage reaction system wherein (i) the reactant stream flows serially through the plurality of reaction zones and, (ii) the catalyst particles are movable through each reaction zone via gravity-flow. More particularly, the described processing technique is adaptable for utilization in vapor-phase systems wherein the conversion reactions are principally endothermic, and where the flow of the hydrocarbonaceous reactant stream, with respect to the downward direction of catalyst particle movement is cocurrent and essentially radial.

Various types of multiple-stage reaction systems have found widespread utilization throughout the petroleum and petrochemical industries for effecting a variety of reactions, and especially hydrocarbon conversion reactions. Such reactions are either exothermic, or endothermic, and encompass both hydrogen-producing and hydrogen-consuming processes. Multiple-stage reaction systems generally take one of two forms: (1) side-by-side configuration with intermediate heating between the reaction zones, and wherein the reactant stream or mixture flows serially from one zone to another zone; and, (2) a stacked design wherein a single reaction chamber, or more, contains the multiple catalytic contact stages. As applied to petroleum refining, such reactor systems have been employed to effect numerous hydrocarbon conversion reactions including those which are prevalent in catalytic reforming, alkylation, ethylbenzene dehydrogenation to produce styrene, other dehydrogenation processes, etc. Our invention is specifically intended for utilization in those processes where the conversion reactions are effected in vapor-phase, catalyst particles are movable via gravity-flow, where the reaction system exists in side-by-side relation, where two or more catalytic contact zones are "stacked", or where one or more additional reaction zones are disposed in a side-by-side relationship with the stack.

Since catalyst particles which are movable through a reaction system by way of gravity-flow are necessarily moving in a downwardly direction, the present technique contemplates the withdrawal of catalyst particles from a bottom portion of one reaction zone and the introduction of fresh, or regenerated catalyst particles into the top portion of a second reaction zone. Our technique is also intended to be applied to those reaction systems wherein the catalyst is disposed as an annular-form bed and the flow of the reactant stream, serially from one zone to another reaction zone, is perpendicular, or radial to the movement of catalyst particles.

A radial-flow reaction system generally consists of tubular-form sections, having varying nominal cross-sectional areas, vertically and coaxially disposed to form the reaction vessel. Briefly, the system consists of a reaction chamber containing a coaxially-disposed catalyst-retaining screen, having a nominal, internal cross-sectional area less than said chamber, and a perforated centerpipe having a nominal, internal cross-sectional area which is less than the catalyst-retaining screen. The reactant stream is introduced, in vapor-phase, into the annular-form space created between the inside wall of the chamber and the outside surface of the catalyst-retaining screen. The latter forms an annular-form, catalyst-holding zone with the outside surface of the perforated centerpipe; vaporous reactant flows laterally and radially through the screen and catalyst zone into the centerpipe and out of the reaction chamber. Although the tubular-form configuration of the various reaction zone components may take any suitable shape -- e.g. triangular, square, oblong, diamond, etc. -- many design, fabrication and technical considerations dictate the advantages of utilizing components which are substantially circular in cross-section.

Illustrative of a multiple-stage stacked reaction zone system, to which the present invention is particularly adaptable, is that shown in U.S. Pat. No. 3,706,536 (Cl. 23-288G), issued Dec. 19, 1972. Transfer of the gravity-flowing catalyst particles, from one reaction zone to another, as well as introduction of fresh catalyst particles and the withdrawal of "spent" catalyst particles, is effected through the utilization of a plurality of catalyst-transfer conduits. Experience in the use of such systems, as well as those where the reaction zones are disposed in a side-by-side relationship indicates that the high vapor flow through the annular-form catalyst-holding sections results in catalyst particles being "pinned" in the vicinity of the perforated centerpipe. Created thereby are stagnant catalyst areas where the catalyst particles are prevented from assuming the gravity-flow pattern.

OBJECTS AND EMBODIMENTS

A principal object of our invention is to prevent, or alleviate catalyst "pinning" in a hydrocarbon conversion system in which catalyst particles are movable via gravity-flow. A corollary objective is to provide an improved processing technique for utilization in a multiple-stage, stacked reactor system in which catalyst particles in each reaction zone are movable via gravity-flow, and catalyst particles flow from one zone to the next succeeding reaction zone by way of gravity-flow.

Another object afforded through the use of our inventive concept is improvement in a substantially endothermic hydrocarbon conversion system effected in vapor-phase and wherein the catalyst particles are downwardly movable via gravity-flow.

Therefore, in a multiple-stage catalytic conversion system, wherein (1) heated hydrocarbonaceous charge stock and hydrogen flow serially through a plurality of catalytic reaction zones; (2) a reaction product effluent from each zone is heated prior to the introduction thereof into the next succeeding reaction zone; and, (3) catalyst particles are movable through each reaction zone via gravity-flow, our invention directs itself toward the method of effecting the conversion of said charge stock which comprises the steps of: (a) heating said charge stock and hydrogen, and introducing the heated mixture into a first reaction zone maintained at hydrocarbon conversion conditions; (b) heating the resulting first reaction zone effluent and introducing the heated effluent into a succeeding reaction zone maintained at hydrocarbon conversion conditions; (c) restricting the flow of the effluent from at least one reaction zone in said plurality and separating the effluent from the last reaction zone to provide (i) a normally liquid product stream and, (ii) a hydrogen-rich vaporous phase; (d) restricting the flow of at least a portion of said hydrogen-rich vaporous phase and recycling said portion to said first reaction zone; (e) at least periodically withdrawing catalyst particles from the last of said reaction zones; and, (f) at least periodically introducing fresh, or regenerated catalyst particles into the first of said reaction zones.

This embodiment is further characterized in that the flow of product effluent from an intermediate reaction zone is restricted prior to the introduction thereof into the next succeeding reaction zone, and the flow of the effluent from the last reaction zone is restricted prior to effecting the separation thereof.

In a more specific embodiment, our invention encompasses a multiple-stage hydrocarbon catalytic reforming process which comprises the steps of: (a) introducing a heated mixture of hydrocarbon charge stock and hydrogen into a first catalytic reaction zone in which catalyst particles are movable via gravity-flow; (b) restricting the flow of the resulting first zone effluent and, (i) heating said effluent and, (ii) introducing said effluent into a second catalytic reaction zone in which catalyst particles are movable via gravity-flow; (c) restricting the flow of the resulting second zone effluent and, (i) heating said effluent and, (ii) introducing said effluent into a third catalytic reaction zone in which catalyst particles are movable via gravity-flow; (d) restricting the flow of the resulting third zone effluent and, (i) heating said effluent and, (ii) introducing said effluent into a fourth catalytic reaction zone in which catalyst particles are movable via gravity-flow; (e) restricting the flow of the resulting fourth zone effluent and separating the same to provide (i) a normally liquid product effluent and, (ii) a hydrogen-rich vaporous phase; (f) restricting the flow of at least a portion of said hydrogen-rich vaporous phase and recycling said portion to said first reaction zone; (g) at least periodically withdrawing catalyst particles from said fourth reaction zone; and, (h) at least periodically introducing fresh, or regenerated catalyst particles into said first reaction zone.

This embodiment is further characterized in that the four reaction zones are disposed as a vertical stack having a common vertical axis, and catalyst particles are movable from one reaction zone to the next succeeding reaction zone via gravity-flow.

These, as well as other objects and embodiments will become evident from the following, more detailed description of the present hydrocarbon conversion process. In one such other embodiment, each restriction of effluent flow produces an additional reactor system pressure drop in the range of about 1.0 psi. to about 10.0 psi. Similarly, the restriction of the flow of the recycled portion of the hydrogen-rich vaporous phase produces an additional reactor system pressure drop of about 1.0 psi. to about 10.0 psi.

PRIOR ART

It must be recognized and acknowledged that various types of hydrocarbon conversion processes utilize multiple-stage reactor systems, either in a side-by-side configuration, as a vertically-disposed stack, or a combination of a stacked system in side-by-side relation with one or more separate reaction zones. As applied to petroleum refining, such systems may be employed in a wide variety of hydrocarbon conversion reactions. While our inventive concept is adaptable to many conversion reactions and processes, through the reactor system of which the catalyst particles are movable via gravity-flow, the same will be further described in conjunction with the well known emdothermic catalytic reforming process.

Historically, catalytic reforming was effected in a non-regenerated, fixed-bed system comprising a plurality of reaction zones disposed in side-by-side relation. When the catalytic composite became deactivated to the extent that continuous operation was no longer economically feasible, the entire unit was shut-down and the catalyst regenerated in situ. Of a more recent vintage, was the so-called "swing bed" system in which an extra reactor was substituted for one which was due to be placed off-stream for regeneration purposes. Still more recently, multiple-stage reactor systems have been provided in which the catalyst particles flow, via gravity, through each reaction zone. In a "stacked" system, the catalyst particles also flow downwardly from one catalyst-containing zone to another, and ultimately transfer to a suitable regeneration system also preferably functioning with a downwardly-moving bed of catalyst particles. In effect, the catalyst particles are maintained from one section to another in a manner such that the flow of catalyst particles in continuous, at frequent intervals, or at extended intervals with the movement being controlled by the quantity of catalyst withdrawn from the last of the series of individual reaction zones.

U.S. Pat. No. 3,470,090 (Cl. 208-138), issued Sept. 30, 1969, illustrates a multiple-stage, side-by-side reaction system with intermediate heating of the reactant stream which flows serially through the individual reaction zones. Catalyst particles which are withdrawn from any one of the reaction zones are transported to suitable regeneration facilities. This type of system can be modified to the extent that the catalyst particles withdrawn from a given reaction zone are transported to the next succeeding reaction zone, wile the catalyst withdrawn from the last reaction zone may be transported to a suitable regeneration facility. The necessary modifications can be made in a manner disclosed in U.S. Pat. No. 3,839,197 (Cl. 208-174), issued Oct. 1, 1974, involving an inter-reactor catalyst transport method. Catalyst transfer from the last reaction zone in the plurality to the top of the catalyst regeneration zone is made possible through the use of the technique illustrated in U.S. Pat. No. 3,839,196 (Cl. 208-174), also issued Oct. 1, 1974.

A stacked reaction zone configuration is shown in U.S. Pat. No. 3,647,680 (Cl. 208-65), issued Mar. 7, 1972, as a two-stage system having an integrated regeneration facility which receives that catalyst withdrawn from the bottom, or last reaction zone. Similar stacked configurations are illustrated in U.S. Pat. No. 3,692,496 (Cl. 23-288G), issued Sept. 19, 1972, and U.S. Pat. No. 3,725,249 (Cl. 208-139), issued Apr. 3, 1973.

U.S. Pat. No. 3,725,248 (Cl. 208-138), issued Apr. 3, 1973, illustrates a multiple-stage system in side-by-side configuration with gravity-flowing catalyst particles being transported from the bottom of one reaction zone to the top of the next succeeding reaction zone, those catalyst particles being removed from the last reaction zone are transferred to suitable regeneration facilities.

As hereinbefore stated, general details of a three-reaction zone, stacked system are presented in U.S. Pat. No. 3,706,536 (Cl. 23-288G), issued Dec. 19, 1972, and illustrates one type of multiple-stage system to which the present inventive concept is applicable. As generally practiced in a catalytic reforming unit, each succeeding reaction zone contains a greater volume of catalyst in that the annular-form, catalyst-holding zone is greater in cross-sectional area.

These illustrations are believed to be fairly representative of the art which has been developed in multiple-stage conversion systems wherein catalyst particles are movable through each rection zone via gravity-flow. Noteworthy is the fact that none recognize the existence of stagnant catalyst areas resulting when catalyst particles are pinned to the perforated centerpipe by the lateral/radial vapor flow across the annular-form catalyst bed. Likewise, it is readily ascertained that there is no recognition of restricting either the reaction zone effluent flow, or the recycled hydrogen flow.

U.S. Pat. No. 3,864,240 (Cl. 208-64), issued Feb. 4, 1975, is illustrative of the integration of a reaction system having gravity-flowing catalyst particles with a fixed-bed system. As stated in this reference, one of the advantages resides in revamping in existing three-reaction zone, fixed-bed system to conform to the integrated system. It is suggested that a second compressor be added to provide split-flow of hydrogen-rich recycle gas. The use of the additional compressor would be to supply the necessary hydrogen recycle to the moving-bed portion of the system, while the original compressor supplies hydrogen recycle to the plurality of fixed-bed reaction zones. Therefore, the moving-bed reaction zone must accommodate all the vaporous material in the system including the recycle hydrogen from its own compressor and the total effluent from the last of the fixed-bed reaction zone. Again, there is no recognition of the difficulties attendant catalyst pinning in the zone where the catalyst particles are movable via gravity-flow. Quite obviously, this particular pinning problem is non-existent in a fixed-fed reaction system.

In brief summation, the prior art directed toward catalytic conversion systems in which catalyst particles are movable via gravity-flow, is not cognizant of the existence of a catalyst pinning problem and its attendant difficulties. Furthermore, the restriction of the flow of product effluent, upon which the present invention concept is founded, in addition to restriction of the flow of recycle hydrogen, is not recognized.

SUMMARY OF INVENTION

To reiterate briefly, the process encompassed by our inventive concept is suitable for use in hydrocarbon conversion systems which are characterized as multiple-stage, and in which catalyst particles are movable via gravity-flow through each reaction zone. Furthermore, the present invention is principally intended for utilization in reactor systems where the principal reactions are endothermic and are effected in vapor-phase. Although the following discussion is specifically directed toward catalytic reforming of naphtha boiling range fractions, there is no intent to so limit the present invention. Catalytic reforming, as well as many other processes, has experienced several phases of development currently terminating in the system in which the catalyst beds assume the form of a descending column in one or more reaction vessels. Typically, the catalysts are utilized in substantially spherical form having a nominal diameter ranging from about 1/32-inch to about 5/32-inch in order to offer free-flow characteristics which will neither bridge, nor block the descending column, or columns of catalyst within the overall system.

In one such multiple-stage system, the reaction chambers ae vertically stacked and a plurality, generally from about 6 to about 16, of relatively small diameter conduits are employed to transfer catalyst particles from one reaction zone to the next lower reaction zone (via gravity-flow) and ultimately to withdraw catalyst particles from the last reaction zone. The latter are usually transported to the top of a catalyst regeneration facility, also functioning with a descending column of catalyst particles; regenerated catalyst particles are then transported to the top of the upper reaction zone of the stack. In order to facilitate and enhance gravity-flow within each reaction vessel, as well as from one zone to another, it is particularly important that the catalyst particles have a relatively small nominal diameter, and one which is preferably less than about 5/32-inch. In a conversion system having the individual gravity-flow reaction zones in side-by-side relationship, catalyst transport vessels (of the type shown in U.S. Pat. No. 3,839,197) are employed in transferring the particles from the bottom of one zone to the top of the succeeding zone, and from the last reaction zone to the top of the regeneration facility.

Catalytic reforming of naphtha boiling range hydrocarbons, a vapor-phase operation, is effected at conversion conditions including catalyst bed temperatures in the range of about 700° F. to about 1020° F.; judicious and cautious techniques generally dictate that catalyst temperatures not substantially exceed a level of about 1020° F. Other conditions include a pressure from about 50 psig. to about 1000 psig., a liquid hourly space velocity (defined as volumes of fresh charge stock per hour, per volume of total catalyst particles) in the range of about 0.2 to about 10.0 and a hydrogen to hydrocarbon mole ratio generally in the range of about 0.5:1.0 to 10.0:1.0. As those possessing the requisite skill in the petroleum refining art are aware, the described continuous regenerative reforming system offers numerous advantages when compared to the prior art fixed-bed systems. Among these is the capability of efficient operation at comparatively lower pressures -- e.g. 50 psig. to about 200 psig. -- and higher liquid hourly space velocities -- e.g. about 3.0:1.0 to about 8.0:1.0. As a result of continuous catalyst regeneration, higher consistent inlet catalyst bed temperatures can be maintained -- e.g. 950° F. to about 1010° F. Furthermore, there is afforded a corresponding increase in both hydrogen production and hydrogen purity in the recycled vaporous phase from the product separation facility.

Catalytic reforming reactions are varied, and include dehydrogenation of napthenes to aromatics, dehydrocyclization of paraffins to aromatics, hydrocracking of long-chain paraffins into lower-boiling, normally-liquid material and, to a certain extent, the isomerization of paraffins. These reactions, the net result of which is endothermicity, with respect to the overall reaction system, are effected through the utilization of one or more Group VIII noble metals (e.g. platinum, iridium, rhodium, palladium) combined with a halogen (e.g. chlorine and/or fluorine) and a porous carrier material such as alumina. Relatively recent investigations have indicated that more advantageous results are attainable and enjoyed through the cojoint use of a catalytic modifier; these have been selected from the group of cobalt, nickel, gallium, germanium, tin, rhenium, vanadium and mixtures thereof, etc. Regardless of the selected catalytic composite, the ability to attain the advantage over the common fixed-bed systems is greatly dependent upon achieving acceptable catalyst particle flow downwardly through the system. Not only must this be substantially uniform throughout the cross-section of the annular catalyst bed, but stagnant areas of catalyst must be maintained at the most achievable minimum.

Catalytic reforming is a well known process which has been thoroughly described in the literature, having been a commercially important tool of the petroleum refining industry for about three decades. One of the many things gleaned from the vast amount of catalytic reforming experience and resulting knowledge, is the soundness of utilizing multiple stages, each of which contains a different quantity of catalyst, generally expressed as volume percent. The reactant stream, hydrogen and the hydrocarbon feed, flow serially through the reaction zones in order of increasing catalyst volume with, of course, interstage heating. In a three-reaction zone system, typical catalyst loadings are: first, 10.0% to about 30.0%; second, from about 20% to about 40.0%; and, third, from about 40.0% to about 60.0%. With respect to a four-reaction zone system, suitable catalyst loadings would be: first, 5.0% to about 15.0%; second, 15.0% to about 25.0%; third, 25.0% to about 35.0%; and, fourth, 35.0% to about 50.0%. Unequal catalyst distribution, increasing in the serial direction of reactant stream flow, facilitates and enhances the distribution of the reactions as well as the overall heating of reaction.

As hereinbefore stated, the pinning of catalyst particles to the perforated centerpipe stems primarily from the high vapor velocity laterally across the annular-form catalyst-holding zone, this adverse effect increasing in degree as the cross-sectional area and length of the catalyst bed decreases. In multiple-stage catalytic reforming systems, therefore, the effect is most pronounced in the first and second reaction zones, having the smaller annular cross-sectional areas, somewhat less in the third reaction zone and of a relatively minor consequence in the fourth reaction zone due to its length and larger cross-sectional catalyst area. Restricting the flow of the product effluent from the last reaction zone in the serial plurality will reduce the degree of catalyst pinning. Preferably, the flow of the product effluent from all the reaction zones is restricted prior to the introduction thereof into the next succeeding reaction zone, or with respect to the last reaction zone, prior to the separation thereof into the normally liquid product and the hydrogen-rich vaporous phase. In a four-zone system, with respect to the intermediate reaction zones, being numbers 2 and 3 in a four-zone system, it is preferred to restrict the flow of effluent therefrom in addition to that emanating from the fourth reaction zone, with or without restriction of the first reaction zone effluent.

The flow restriction of the various reaction zone effluents may be effected in any suitable manner which produces, or results in an additional pressure drop increase, for the overall reactor circuit, of from about 1.0 psi. to about 10.0 psi. for each such restriction. Similarly, it is intended that the restriction of the flow of the recycled hydrogen-rich vaporous phase produce an additional pressure drop increase of about 1.0 psi. to about 10.0 psi. Flow restriction may be accomplished through the use of venturi tubes, orifice plates, etc.; the orifice plate is particularly preferred for the vapor-phase operation. For the most part, catalyst pinning is a function of two dependent variables: (1) the vapor mass flow rate; and, (2) the density of the vapors which flow laterally through the annular-form catalyst bed into and through the perforated centerpipe. To reduce, or eliminate catalyst pinning, for a given design flow of fresh feed charge stock, the rate of hydrogen-rich gas recycle to the system must be reduced. This, however, reduces the total mass flow to a given reaction zone, which, in turn, reduces the reactor system pressure drop. Of course, the effective pressure in the initial reaction zone, in which catalyst pinning is most prevalent and troublesome, is reduced; a corresponding reduction in vapor density ensues. The utilization of restriction orifices (or other suitable devices) between reaction zones and in the hydrogen recycle conduit, increases the pressure drop in the reactor circuit; this increases the pressure in the first reaction zone and thus the density of the vapors. Higher vapor density alleviates the catalyst pinning problems. The use of restriction orifices also affords greater recycle gas flow which reduces carbonaceous material deposition in the regeneration load imposed upon the regeneration facility. Furthermore, the final reaction zone functions at a lower pressure which gives rise to a liquid yield advantage. Preferably, the restriction orifices are placed upstream of the reaction zone inter-heaters to decrease the heater operating pressure and increase the velocity of the reactor effluent in the heater tubes. Similarly, a common practice is to heat-exchange the mixture of charge stock and recycled hydrogen against the hot reaction zone effluent emanating from the last reaction zone, prior to the introduction thereof into the charge stock heater. In accordance with the preferred mode of effecting the present invention, the recycle hydrogen flow is restricted prior to the heat exchanger. While the restriction of recycled hydrogen flow does not contribute to the solution of the catalyst pinning problem to as great an extent as the restrictions of reaction zone effluent, it does serve a useful and advantageous function in conjunction therewith. This restriction orifice insures proper hydrogen distribution to the combined feed heat-exchanger which generally consists of at least two parallel shells of exchange. In effect, they reinstate the pressure drop lost while operating at reduced hydroen to hydrocarbon mole ratios and lower reaction zone pressures.

BRIEF DESCRIPTION OF DRAWING

In further describing the present invention, and its method of operation, reference will be made to the accompanying drawing. It is understood that the drawing is presented solely for the purposes of illustration, and the same is not intended to be construed as limiting upon the scope and spirit of our invention as defined by the appended claims. Therefore, miscellaneous appurtenances, not required for a complete understanding of the inventive concept, have been eliminated or reduced in number. Such items are well within the purview of one possessing the requisite skill in the appropriate art. The illustrated embodiment is presented as a simplified schematic flow diagram showing four reaction zones, stacked catalytic reforming system 1 having an upper first reaction zone I, two intermediate zones II and III, and a lowermost fourth reaction zone IV.

DETAILED DESCRIPTION OF DRAWING

The drawing illustrates the particularly preferred embodiment in which the product effluent from each of the reaction zones is restricted, in addition to the restriction of the flow of hydroen-rich recycle gas. With respect to the four reaction zones I, II, III and IV, this is accomplished through the use of restriction orifices 10, 14, 18 and 22, respectively. The flow of the hydrogen-rich recycle gas is restricted through the utilization of restriction orifice 3.

Stacked, gravity-flowing catalytic reaction system 8 is shown as having four individual reaction zones which are sized as to length and annular catalyst cross-sectional area such that the distribution of the total catalyst volume is 10.0% (zone I), 15.0% (zone II), 25.0% (zone III) and 50.0% (zone IV). In a normal, substantially problem-free operation, fresh or regenerated catalyst particles are introduced through conduit 29 and inlet port 30 into the uppermost zone I and flow via gravity therefrom into reaction zone II, from zone II into zone III, from zone III into zone IV, and are ultimately withdrawn from the reactor system through a plurality of outlet ports 31 and conduits 32. Catalyst particles so removed may be transported to a continuous regeneration zone (not illustrated), or may be stored until a sufficient quantity is available for a batch-wise regeneration. The rate of catalyst flow through stacked reactor system 8, or the period of time required for catalyst particles to be introduced into the system, traverse the four reaction zones and be withdrawn for regeneration, is determined by the rate at which the latter is effected. By monitoring various operating parameters while the system is in continuous operation, the catalyst withdrawal rate, or regeneration load can be controlled.

The naphtha boiling range charge stock is introduced into the process by way of line 1, admixed with a hydrogen-rich vaporous phase from line 2, containing a restriction orifice 3 having a rating of about 6.0 psi., and introduced into heat-exchanger 4. The temperature of the mixture is increased by way of indirect heat-exchange with hot product effluent entering by way of line 21. The thus-heated mixture continues through conduit 5 into charge heater 6, and therefrom through line 7 into uppermost reaction zone I at a temperature required to provide the desired temperature at the inlet to the first catalyst bed disposed therein.

Reaction product effluent from catalyst zone I passes through line 9, containing restriction orifice 10 rated at about 5.0 psi., into inter-heater 11, and therefrom through line 12 into first intermediate reaction zone II. Product effluent from catalyst zone II is withdrawn by way of line 13, containing a restriction orifice 14 rated at about 6.0 psi., and is introduced thereby into inter-heater 15; the heated vaporous material is introduced into second intermediate reaction zone III by way of conduit 16. Conduit 17, containing a restriction orifice 18, also rated at 6.0 psi., carries the effluent from catalytic zone III into inter-heater 19, the heated mixture being introduced into lower most reaction zone IV by way of line 20.

The reaction product effluent from lowermost catalytic zone IV is withdrawn by way of line 21, containing restriction orifice 22 having a rating of about 7.0 psi. The product effluent continues through conduit 21 and is utilized as the heat-exchange medium in heat-exchanger 4. Thus cooled, the product effluent passes through line 23 into condenser 24 wherein cooling and condensation takes place at a temperature in the range of about 60° F. to about 140° F., and the mixture passes through line 25 into separation zone 26. Hydrogen-rich vaporous material is withdrawn through conduit 2, containing restriction orifice 3, for recycle at least in part to uppermost reaction zone I; excess hydrogen is withdrawn from the process through line 28, the rate being determined by suitable pressure control. The normally liquid product effluent is withdrawn by way of line 27 and introduced thereby into suitable fractionation facilities (not illustrated).

Although indicated as a single separation vessel 26 and condenser 24, it will be recognized by those possessing the requisite skill in the appropriate art that the separation of the product effluent in line 25 may be effected using an initial low pressure separator followed by a high pressure separator. Vaporous material from the low pressure separator is compressed and introduced into a high pressure cooler in admixture with the liquid material recovered from the low pressure separator. The mixture is then introduced into the high pressure separator from which the hydrogen-rich recycle vaporous phase and a normally liquid product effluent are recovered.

It is believed that the foregoing, when considered in conjunction with the accompanying drawing presents a clear understanding of the technique encompassed by the present invention. Through the implementation thereof, the catalyst pinning problem which adversely affects uniform catalyst flow characteristics throughout the reactor system is substantially alleviated. 

We claim as our invention:
 1. In a multiple-stage catalytic conversion system, wherein (1) heated hydrocarbonaceous charge stock and hydrogen flow serially through a plurality of catalytic reaction zones; (2) the reaction product effluent from each zone is heated prior to the introduction thereof into the next succeeding reaction zone; and, (3) catalyst particles are movable through each reaction zone via gravity-flow, the method of effecting the conversion of said charge stock which comprises the steps of:(a) heating said charge stock and hydrogen, and introducing the heated mixture into a first reaction zone maintained at hydrocarbon conversion conditions; (b) heating the resulting first reaction zone effluent and introducing the heated effluent into a succeeding reaction zone maintaned at hydrocarbon conversion conditions; (c) restricting the flow of the effluent from at least one reaction zone by means of a fixed restriction orifice in said plurality and separating the effluent from the last reaction zone to provide (i) a normally liquid product stream and, (ii) a hydrogen-rich vaporous phase; (d) restricting the flow by means of a fixed restriction orifice of at least a portion of said hydrogen-rich vaporous phase and recycling said portion to said first reaction zone, each of said flow restrictions in steps (c) and (d) producing an additional pressure drop increase, for the overall reactor system, of from about 1.0 to about 10.0 psi; (e) at least periodically withdrawing catalyst particles from the last of said reaction zones; and, (f) at least periodically introducing fresh, or regenerated catalyst particles into the first of said reaction zones.
 2. The method of claim 1 further characterized in that the flow of product effluent from the last reaction zone is restricted prior to effecting the separation thereof.
 3. The method of claim 1 further characterized in that the flow of product effluent from an intermediate reaction zone is restricted prior to the introduction thereof into the next succeeding reaction zone, and the flow of the effluent from the last reaction zone is restricted prior to effecting the separation thereof.
 4. The method of claim 1 further characterized in that the reaction zones in said plurality are disposed in side-by-side relationship and catalyst particles are transferred from the bottom of one reaction zone to the top of the next succeeding reaction zone.
 5. The method of claim 1 further characterized in that the reaction zones in said plurality are stacked and share a common vertical axis, and catalyst particles flow via gravity from one reaction zone to the next lower reaction zone in said stack.
 6. The method of claim 1 further characterized in that said plurality contains at least three catalytic reaction zones.
 7. The method of claim 6 further characterized in that the product effluent flow from each of said three reaction zones is restricted.
 8. The method of claim 1 further characterized in that said plurality contains four catalytic reaction zones.
 9. The method of claim 8 further characterized in that the flow of the effluent from each of only the last three reactions zones is restricted.
 10. The method of claim 8 further characterized in that the product effluent flow from each of the four reaction zones is restricted.
 11. A multiple-stage hydrocarbon catalytic reforming process which comprises the steps of:(a) introducing a heated mixture of hydrocarbon charge stock and hydrogen into a first catalytic reaction zone in which catalyst particles are movable via gravity-flow; (b) restricting the flow of the resulting first zone effluent and, (i) heating said effluent and, (ii) introducing said effluent into a second catalytic reaction zone in which catalyst particles are movable via gravity-flow; (c) restricting the flow of the resulting second zone effluent and, (i) heating said effluent and, (ii) introducing said effluent into a third catalytic reaction zone in which catalyst particles are movable via gravity-flow; (d) restricting the flow of the resulting third zone effluent and, (i) heating said effluent and, (ii) introducing said effluent into a fourth catalytic reaction zone in which catalyst particles are movable via gravity-flow; (e) restricting the flow of the resulting fourth zone effluent and separating the same to provide (i) a normally liquid product effluent and, (ii) a hydrogen-rich vaporous phase; (f) restricting the flow of at least a portion of said hydrogen-rich vaporous phase and recycling said portion to said first reaction zone; (g) at least periodically withdrawing catalyst particles from said fourth reaction zone; and, (h) at least periodically introducing fresh, or regenerated catalyst particles into said first reaction zone.
 12. The process of claim 11 further characterized in that said four reaction zones are disposed as a vertical stack having a common vertical axis, and catalyst particles are movable from one reaction zone to the next succeeding reaction zone via gravity-flow.
 13. The process of claim 11 further characterized in that each restriction of effluent flow produces an additional reactor system pressure drop in the range of about 1.0 psi. to about 10.0 psi.
 14. The method of claim 11 further characterized in that the restriction of the flow of the recycled portion of said hydrogen-rich vaporous phase produces an additional reactor system pressure drop of about 1.0 psi. to about 10.0 psi. 